Improving neuronal adhesion on chip using a phagocytosis-like event

Bart van Meerbergen; Tim Raemaekers; Kurt Winters; Dries Braeken; Carmen Bartic; Micha Spira; Yves Engelborghs; Wim Annaert; Gustaaf Borghs

doi:10.1080/17458080600900347

Improving neuronal adhesion on chip using a phagocytosis-like event

Bart van Meerbergen^*, Tim Raemaekers, Kurt Winters, Dries Braeken, Carmen Bartic, Micha Spira, Yves Engelborghs, Wim Annaert, Gustaaf Borghs

^*Corresponding author for this work

Alexander Silberman Institute of Life Sciences

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Efficient integration of neuronal cells and electronic devices could result in hybrid bi-directional communication systems that would enable us to interact at fundamental levels with biological structures and gain insight in the mechanisms governing their functions. Such systems require a very tight coupling between the neuronal cell membrane and the surface of an electronic chip. In this paper we report an approach where the combination of specialized surface chemistry and the manipulation of biological processes, like a phagocytosis-like process, might improve this coupling. As a model, we used coated micro- and nano-sized beads and induced phagocytosis-like events by adding them to cultured cells. The development of the surface chemistry and the results obtained with beads functionalized with a laminin derived peptide are presented.

Original language	English
Pages (from-to)	101-114
Number of pages	14
Journal	Journal of Experimental Nanoscience
Volume	2
Issue number	1-2
DOIs	https://doi.org/10.1080/17458080600900347
State	Published - Mar 2007

Keywords

Functionalized nanobeads
Neuronal adhesion
Surface chemistry

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10.1080/17458080600900347

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AU - van Meerbergen, Bart

AU - Raemaekers, Tim

AU - Winters, Kurt

AU - Braeken, Dries

AU - Bartic, Carmen

AU - Spira, Micha

AU - Engelborghs, Yves

AU - Annaert, Wim

AU - Borghs, Gustaaf

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AB - Efficient integration of neuronal cells and electronic devices could result in hybrid bi-directional communication systems that would enable us to interact at fundamental levels with biological structures and gain insight in the mechanisms governing their functions. Such systems require a very tight coupling between the neuronal cell membrane and the surface of an electronic chip. In this paper we report an approach where the combination of specialized surface chemistry and the manipulation of biological processes, like a phagocytosis-like process, might improve this coupling. As a model, we used coated micro- and nano-sized beads and induced phagocytosis-like events by adding them to cultured cells. The development of the surface chemistry and the results obtained with beads functionalized with a laminin derived peptide are presented.

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Improving neuronal adhesion on chip using a phagocytosis-like event

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Keywords

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